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| United States Patent |
5,640,283
|
|
Warren
|
June 17, 1997
|
Wide field, long focal length, four mirror telescope
Abstract
An all reflective telescope system generally includes two spherical
mirrors, one mild aspheric mirror and one aspheric mirror all centered
about a common telescope axis and imaging on a focal surface for easy
manufacture, very long focal length, wide field of view, high resolution,
compact volume and low weight particularly well suited for space
observations, and in a detailed form includes a sectional concave
hyberboloidal primary mirror, a circular mild convex ellipsoidal secondary
mirror, a sectional concave spherical tertiary mirror and a sectional
convex spherical quaternary mirror for focusing an extended distant object
onto a concave cylindrical focal surface having a linear array of charge
coupled detectors for high resolution imagery, the telescope having high
performance operation near diffraction limits and operating at detector
resolution limits.
| Inventors:
|
Warren; David Wheeler (Los Angeles, CA)
|
| Assignee:
|
The Aerospace Corporation (El Segundo, CA)
|
| Appl. No.:
|
546426 |
| Filed:
|
October 20, 1995 |
| Current U.S. Class: |
359/859; 359/366; 359/729; 359/731 |
| Intern'l Class: |
G02B 017/00; G02B 005/10 |
| Field of Search: |
359/364-366,726-732,850-861
|
References Cited
U.S. Patent Documents
| 4189236 | Feb., 1980 | Hogg et al. | 359/859.
|
| 4598981 | Jul., 1986 | Hallam et al. | 359/366.
|
| 5142417 | Aug., 1992 | Brunn | 359/859.
|
| 5144476 | Sep., 1992 | Kebo | 359/859.
|
| 5410434 | Apr., 1995 | Shafer | 359/859.
|
Primary Examiner: Nguyen; Thong
Attorney, Agent or Firm: Reid; Derrick M.
Goverment Interests
STATEMENT OF GOVERNMENT INTEREST
This invention was made with Government support under contract number
F04701-88-C-0089 awarded by the Department of the Air Force. The
Government has certain rights in the invention.
Claims
I claim:
1. A telescope for imaging an image of an object from a distance onto a
focal surface, said telescope having a common axis, said telescope
comprising:
a concave primary mirror having a parent surface centered about said common
axis and for collecting and reflecting said image of said object, said
image following a path from said object and angularly tilted from said
common axis;
a convex secondary mirror centered about said common axis and for receiving
and reflecting said image reflected from said primary mirror;
a concave tertiary mirror having a parent surface centered about said
common axis and for receiving and reflecting said image from said
secondary mirror; and
a convex quaternary mirror having a parent surface centered about said
common axis and for receiving and reflecting said image from said tertiary
mirror, the convex reflective quaternary mirror is for reflecting said
image onto said focal surface.
2. The telescope of claim 1 further comprising a plurality of detectors
disposed along said focal surface.
3. The telescope of claim 1 wherein
said concave primary mirror is an eccentric section of a concave
hyperboloid of revolution,
said convex secondary mirror is a mild circular convex ellipsoid,
said concave tertiary mirror is an eccentric section of a concave sphere,
and
said convex quaternary mirror is an eccentric section of convex sphere.
4. The telescope of claim 1 further comprising a plurality of detectors
disposed along said focal surface, said plurality of detectors being a
linear array of charge coupled devices aligned as a concave cylindrical
linear array providing detector limited image resolution of said image.
5. A telescope for imaging an image of an object from a distance onto a
focal surface, said telescope having a common axis, said telescope
comprising:
a concave primary mirror having a parent surface centered about said common
axis and for collecting and reflecting said image of said object, said
image following a path from said object and angularly tilted from said
common axis;
a convex secondary mirror centered about said common axis and for receiving
and reflecting said image reflected from said primary mirror;
a concave tertiary mirror having a parent surface centered about said
common axis and for receiving and reflecting said image from said
secondary mirror; and
a convex quaternary mirror having a parent surface centered about said
common axis and for receiving and reflecting said image from said tertiary
mirror, the convex reflective quaternary mirror is for reflecting said
image onto said focal surface, and wherein,
said telescope is defined by a field of view, an effective focal length and
an effective aperture size, said field of view is greater than five
degrees and said focal length is greater than 12 times said effective
aperture size.
6. The telescope of claim 5 further comprising a plurality of detectors
disposed along said focal surface.
7. The telescope of claim 5 wherein
said concave primary mirror is an eccentric section of a concave
hyperboloid of revolution,
said convex secondary mirror is a mild circular convex ellipsoid,
said concave tertiary mirror is an eccentric section of a concave sphere,
and
said convex quaternary mirror is an eccentric section of convex sphere.
8. The telescope of claim 5 further comprising a plurality of detectors
disposed along said focal surface, said plurality of detectors being a
linear array of charge coupled devices aligned as a concave cylindrical
linear array providing detector limited image resolution of said image.
9. A telescope for imaging an image of an object from a distance onto a
focal surface, said telescope having a common axis, said telescope
comprising:
a concave primary mirror having a parent surface centered about said common
axis and for collecting and reflecting said image of said object, said
image following a path from said object and angularly tilted from said
common axis;
a convex secondary mirror centered about said common axis and for receiving
and reflecting said image reflected from said primary mirror;
a concave tertiary mirror having a parent surface centered about said
common axis and for receiving and reflecting said image from said
secondary mirror; and
a convex quaternary mirror having a parent surface centered about said
common axis and for receiving and reflecting said image from said tertiary
mirror, the convex reflective quaternary mirror is for reflecting said
image onto said focal surface, and wherein,
said telescope is defined by a field of view, an effective focal length and
an effective aperture size,
said angular tilt is 5.0 degrees from said common axis,
said focal length is 12.31 times said effective aperture size,
said field of view is +/-2.8 degrees,
said concave primary mirror and said convex secondary mirror together
define an entrance pupil diameter of 505 mm which is equal to said
effective aperture size,
said image on said focal surface has diffraction limited image quality at a
nominal wavelength of 560 mm,
said concave primary mirror is an eccentric section of a concave
hyperboloid of revolution having a radius of curvature of 6538.649 mm, a
conic coefficient of -1.954, and spacing of 1,600.00 mm from said entrance
plane and is in the shape of an oblong,
said convex secondary mirror is a mild circular convex ellipsoid having a
radius of curvature of 2292.043 mm, a conic coefficient of -0.773, a
spacing of 1,599.15 mm from said concave primary mirror and is circular
with a diameter of 258 mm,
said concave tertiary mirror is an eccentric section of a concave sphere
having a radius of curvature of 3971.116 mm, a conic coefficient of 0.0, a
spacing of 1,688,923 mm from said convex secondary mirror and is oblong,
said convex quaternary mirror is an eccentric section of convex sphere,
having a radius of curvature 8513.561 mm, a conic coefficient of 0.0, a
spacing of 1,800,000mm from said concave tertiary mirror and is oblong,
and
said focal surface is section of a concave cylinder having a radius of
curvature of 3342.075 mm, a conic coefficient of 0.0 and a linear focal
surface with a spacing of 1999.802 mm from said convex quaternary mirror.
Description
FIELD OF INVENTION
The present invention relates to reflective optical systems for imaging
distant objects. More specifically, the present invention relates to a
four mirror reflective optical system having a relatively long effective
focal length for high resolution imaging of a distant object.
BACKGROUND OF THE INVENTION
Telescope optical systems are designed to focus light from a distant object
occupying a finite field of view onto an image focal surface. High
definition, high resolution, sharp images require a high spatial frequency
content in the image. However, the frequency content can be degraded by
optical aberrations which blur the image, increasing the image spot size
thereby decreasing image resolution. Telescope optical systems comprise
optical elements which focus light while simultaneously attempting to
eliminate optical aberrations of the image, including spherical
aberration, coma, astigmatism, field curvature and distortion. Two broad
categories of optical systems have been used to collect and focus light
from a distant object. An all-refracting system may comprise a negative
diverging lens disposed between two positive converging lenses, whereas an
all-reflective system may comprise a negative convex surface disposed
between two positive concave surfaces. An all-reflective system uses
mirrors to reflect light in desired directions while an all-refractive
system uses lenses to accomplish the same imaging function by refracting
the incoming light, as is well known.
All-reflective mirror systems have two principal advantages over
all-refractive lens systems. All-reflective systems have geometric light
deviating characteristics which are the same for light of any wavelength,
so that imaging performance is not affected by chromatic aberrations as
with refractive systems. All-reflective systems are therefore preferred
for imaging applications which span a broad range of operating wavelengths
because they are not affected by chromatic aberrations.
All-reflective systems also have mirrors that can be made in any desired
size while the sizes of refractive systems are limited by the availability
of high-quality transmissive materials. Large refractive optical systems
may in principle control optical aberrations but may still be impractical
to build due to the difficulty and expense of producing the required
lenses. Large reflective optical systems tend to minimize the expense of
manufactured optical elements while also controlling optical aberrations.
Large reflective mirrors are easier to construct and are lighter in weight
as compared to large refractive lenses. As the size of the telescope
apertures increase, for example, above 30 cm, reflective systems are
increasingly favored because of limits on the size and quality of
refractive materials.
Diffraction limited image quality is a well known goal of optical systems.
For reflective mirrors, the angle of incidence equals the angle of
reflection except near the edges of a finite mirror aperture. In any
finite aperture system, wave phenomena will limit the resolution due to
the size of aperture, which truncates the wavefront causing diffraction.
Each image point has a finite spatial extent which affects the sharpness
of an image, that is, the contrast at the boundaries between the dark and
light elements of the image. Diffraction reduces the abruptness of the
transitions from dark to light, which is perceived as a degradation of
image contrast. The finite aperture size dictates a finite frequency
response causing a progressive reduction in contrast as spatial frequency
increases. If all telescope anomalies were eliminated, there would still
be diffraction because the telescope has a finite size which causes
truncation of the wavefront. Hence, the finite size of the telescope
aperture causes the image point to grow in size. The image point will not
be a perfect image point but a blurred and enlarged image point. Hence,
the edge diffraction of the aperture limits the resolution of any
telescope. It is generally desirable that any telescope be diffraction
limited to achieve the highest resolution possible for a given finite
aperture size.
One difficulty with all-reflective systems is achieving good image quality
over a wide field of view while minimizing the sizes of individual mirrors
and the volume of the telescope package containing the mirror elements. A
single mirror with an appropriately shaped surface is capable of forming a
perfect geometric image of a single object point. The mathematical
description of the surface of the mirror is dictated by the fundamental
requirement that the length of any path from the object to the image be
equal to the length of any other similar path. For an infinitely distant
object point, for example, the theoretical figure which achieves perfect
geometric imagery is the paraboloid of revolution. The ideal mirror shape
produces the best possible geometric image quality for a given pair of
object and image conjugate points. Errors in fabrication distort the
actual mirror surface from the ideal shape and cause the size of the
geometric image to grow, degrading the frequency content of the image.
Even in the absence of errors, diffraction resulting from the finite size
of the collecting mirror aperture places an ultimate lower diffraction
limit on the size of the image spot for a given system. When the geometric
image spot size from the ideal mirror shape with fabrication errors is
smaller than the spot size caused by diffraction, the system is said to be
diffraction limited. Optimum telescope systems operate near the
diffraction limit to provide the highest resolution possible with the
least degradation of the frequency content.
An extended object can be considered as a continuum of object points each
of which is subject to distortion from perfect imaging by diffraction and
optical aberrations. A single mirror surface is generally not capable of
perfect imaging for more than one object point and image point. Except in
special, impractical cases, a single mirror can not form a perfect image
of extended objects. Hence, optical systems must add additional reflective
surfaces to provide near perfect imaging of extended objects. Additional
surfaces provide additional degrees of freedom which define the shapes and
locations of mirror surfaces. Thus, a multiple mirror system has a set of
surfaces and spacings defining path lengths traversed by rays propagating
from the object to the image. The path lengths for each point are equal
for enough object points to span the required angular field of view. A
compromise is reached between less that perfect imagery and
manufacturability of the reflective surfaces. There is design latitude
that does not significantly affect image quality because geometric spots
need only be smaller that the diffraction limit. Design difficulty
increases with an increase in the field of view of the object to be imaged
because of the difficulty in maintaining equal path lengths for an
increasing number of conjugate points. Additional mirror surfaces and more
complex mirror surface shapes have been used to meet the demands of high
quality imaging of large extended objects. The art of optical design
consists of finding the best overall compromise between the performance
and complexity of an imaging system. Obtaining good image quality over a
wide field of view, for example, greater than 2.5 degrees, is difficult in
a multiple mirror, all-reflective system. The task is simplified if the
field of view is restricted to a one-dimensional line in object space,
rather than a two-dimensional circular or square field. This linear field
can be scanned to build up the image of a two-dimensional extended object
over time.
Aspheric surfaces, which cannot be represented as part of a large sphere,
include conic sections such as hyperboloids, paraboloids, ellipsoids and
oblate spheroids. A conic section is one of several possible shapes
derived from an intersection of a plane with a cone. There are also
general aspherics, for which the shape of the surface is represented by a
general polynomial equation in one of several established forms. The use
of aspheric surfaces is well known. For example, ellipsoidal and
hyperboloidal mirrors are described in U.S. Pat. Nos. 4,101,195 and
4,226,501. Both mild and strong aspherics have been used and are
characterized by the extent of departure from spherical. Aspheric surfaces
are more difficult to manufacture than spherical surfaces and are more
complicated to design as part of an optical system. Spherical mirrors are
always symmetric because any section of a spherical mirror is the same as
any other section. This property makes spherical mirrors easy to
manufacture as compared to aspheric mirrors. Aspheric surfaces can,
however, replace several spherical surfaces for the purpose of reducing
aberrations. Between conic sections and general aspheres, the former are
preferred because they are usually easier to fabricate and test.
One prior art telescope with a wide linear field of view is a three mirror
anastigmat reflective triplet shown in FIG. 1 herein and described in U.S.
Pat. No. 4,240,707. FIG. 1 is a cross-sectional view of image rays, focal
surface and mirrors for one object point in a linear field of view. The
linear field of view extends orthogonally to the cross section of the
focal surface, mirrors and image rays of FIG. 1. In this prior art form,
high resolution imaging is achieved with an aperture stop centered on a
convex secondary mirror and with concave primary and tertiary mirrors
eccentric sections of larger symmetric parent reflective surfaces. The
surfaces are typically aspheric, including for example, conic sections,
depending on the field of view and image quality desired. With conic
aspherics, linear fields of view of up to five degrees on a flat focal
surface have been demonstrated. With general aspherics, linear fields up
to 15 degrees have been demonstrated. This reflective triplet operates
most effectively at focal lengths from three to six times the aperture
size; that is, with focal ratios of f/3 to f/6. The focal ratio, often
called the f-number, is the ratio of the focal length divided by the
aperture diameter. In FIG. 1, the distance from the tertiary mirror to the
focal surface is approximately equal to the effective focal length. For
this type of telescope system, the overall system length, as characterized
by the distance from the tertiary mirror to the focal surface, is
typically comparable to the system effective focal length. Long focal
lengths are desired for high resolution imaging but are disadvantageously
limited by practical sizes of the optical system.
Producing a high resolution image is only one of several desired design
goals of a complete optical system. The image must also be detected and
recorded to be useful. Optical imaging systems produce high resolution
output in part by sampling their images with a large number of detector
elements, or pixels. The detector pixel must be small relative to the
image size. A large number of samples may be achieved by reducing the
pixel size or by increasing image size relative to the pixels by
increasing the focal length of the telescope. There is a lower technology
limit to detector pixel sizes. For charge coupled device (CCD) type
detectors, this limit is presently at about 7 micron pixel size. Once this
limit is reached, increased resolution can only be achieved by increasing
image size, which requires an increase in focal length. In an
all-reflective triplet of the type shown in FIG. 1, one way to increase
the focal length of the telescope is by scaling up the whole optical
system while maintaining the relative proportions between the mirror
shapes, sizes and spacings. This increases the size of the image relative
to the detector pixels, producing more samples across the image for
increased resolution. However, this approach results in a large package
length, weight and volume when the end requirement is a system with a very
long effective focal length. An all-reflective triplet with a large
effective focal length may be particularly undesirable in applications
requiring launch into space, where large physical sizes are prohibited by
considerations of weight and cost.
Starting from the prior art reflective triplet of FIG. 1, another way to
increase the effective focal length is to redistribute the converging and
diverging powers of the three mirrors while maintaining the original
spacing between the secondary mirror and the primary and tertiary mirrors.
An example of such a resulting system is shown in FIG. 2. The focal length
of this optical system may be, for example, 12 times the aperture, giving
a focal ratio of f/12. The package size containing the three curved
mirrors remains the same. However, the long effective focal length still
requires that there be a large spacing between the tertiary mirror and the
focal surface, as shown. This long optical path could be folded with a
series of flat mirrors in order to package the system within a smaller
volume. Such mirrors would, however, complicate the system and add
significantly to the weight of the system and so would be disadvantageous
for space applications. A further disadvantage to this approach is that
the surface of best image quality is typically no longer flat, but follows
a curved profile. This makes fabrication of the detector array more
difficult, although a mild curvature can be approximated by a series of
short, flat array segments distributed along an ideal profile.
FIGS. 1 and 2 demonstrate the difficulties encountered in trying to adapt
the prior art three mirror anastigmat design form to applications
requiring a long effective focal length. Either the packaged volume must
become disadvantageously large, or a number of otherwise unnecessary
mirrors must be added to fold the optical path. Either approach is
undesirable fox applications which place a premium on system size and
weight, for instance, those systems launched into space.
Four mirror reflective systems are also known, for example, the one
disclosed in U.S. Pat. No. 5,142,417 at FIG. 2. This optical system
advantageously describes an f/12 to f/20 optical system with a large
effective focal length. This system also advantageously teaches spherical
mirrors for ease of manufacture, but disadvantageously teaches disjointed
mirror axes between the mirrors and a disadvantageously resulting
relatively small angular field of view. This mirror system adds a fourth
mirror to increase the focal length but adds additional telescope design
costs and manufacturing complexity. The disjointed mirror axes
particularly increase system complexity and alignment requirements,
presenting difficult manufacturing challenges. These and other
disadvantages are solved or reduced using the present invention.
SUMMARY OF THE INVENTION
An object of the present invention is to reduce the size of telescopes to
minimize package weight and volume.
Another object of the present invention is to provide a long focal length,
high resolution, all-reflective optical system that is detector technology
limited.
Another object of the present invention is to provide a long focal length,
high resolution, all-reflective optical system that is diffraction
limited.
Still another object of the present invention is to provide an
all-reflective four mirror telescope having two spherical mirrors, one
mild conic aspheric mirror and one stronger conic aspheric mirror.
Yet another object of the present invention is to provide an all-reflective
optical telescope having a wide linear field of view.
Another object of the present invention is to provide a long effective
focal length, all-reflective optical system that is detector limited and
diffraction limited for optimum resolution.
Still another object of the present invention is to provide an
all-reflective optical telescope having a package length which is a
fraction of the effective focal length.
A further object of the present invention is to provide a long focal
length, high resolution, four mirror optical system using two spherical
mirrors, a mild conic aspheric mirror and a strong conic aspheric mirror
with centers of symmetry all aligned to a common mirror axis.
Still a further object of the present invention is to provide an
all-reflective, four mirror telescope having two positive and two negative
mirrors with an unobscured optical path, a long focal length, a wide
linear field of view, high resolution and a small package volume.
A further object of the present invention is to provide a four mirror
optical system using a concave tertiary and convex quaternary spherical
mirrors, a mild convex ellipsoidal secondary mirror and a strong concave
hyperboloidal primary mirror with centers of symmetry aligned to a common
mirror axis.
The present invention is a four mirror reflective optical telescope for
high resolution imaging of distant objects onto a focal surface. The
inventive system includes two positive and two negative reflective mirrors
with centers of symmetry arranged along a common telescope optical axis.
The imaging telescope of the present invention includes a primary,
secondary, tertiary and quaternary reflective mirrors. The primary and
tertiary mirrors are concave while the secondary and quaternary mirror are
convex. The four mirror system has a long effective focal length for high
resolution imaging that can be detector and diffraction limited and
packaged in a small volume.
In the preferred form, the four mirror system enables redistribution of the
optical powers within the system to permit a long effective focal length
to be packaged in a relatively small volume. The extra degree of design
freedom provided by a fourth mirror also enables the use of tertiary and
quaternary mirrors that are spherical instead of aspheric to simplify the
fabrication of the mirror elements. The secondary mirror is preferably a
mild convex ellipsoid functioning as the optical aperture stop. The
secondary mirror is preferably circular, while the primary, tertiary and
quaternary mirror are preferably elongated surfaces which may be
rectangular or oblong, that is, rectangular with rounded corners. In a
preferred form of the invention with maximum resolution, the focal surface
is a curved linear surface well suited for a linear array of detectors.
The four mirrors may be combined to enable imaging on a curved focal
surface for use with linear detector arrays to take advantage of high
resolution detectors, including those incorporating time delay and
integration capabilities for increased sensitivity.
This all-reflective, four mirror optical system has a wide linear field of
view, for example, 6 degrees, long effective focal length, for example
twelve times the system aperture, is packaged in a relative small volume,
can be made light weight, operates with diffraction limited image, quality
and detector limited image quality, and is relatively easier to
manufacture by virtue of including only spherical and conic aspheric
mirror surfaces with centers of symmetry all aligned to a common telescope
axis. These and other advantages will become more apparent from the
following detailed description of the preferred embodiment.
BRIEF DESCRIPTION OF THE DRAWINGS
FIG. 1 is a diagram of a prior art three mirror anastigmatic optical
telescope having a short focal length;
FIG. 2 is a diagram of a prior art three mirror anastigmatic optical
telescope having a long focal length;
FIG. 3 is a diagram of a four mirror anastigmatic telescope having a long
focal length;
FIG. 4 is an isometric view of the four mirror anastigmatic telescope
having a long focal length;
FIG. 5 is a graph of the performance of the four mirror anastigmatic
telescope compared to diffraction limited performance for a system with
the same aperture and focal length; and
FIG. 6 is specific embodiment of a four mirror optical system.
DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENT
Referring to FIGS. 3 and 4, an anastigmatic telescope comprises four
reflective mirrors for imaging a distant extended object onto a focal
surface. The four mirrors include a primary, secondary, tertiary and
quaternary mirror. The primary and tertiary mirrors are both positive.
concave mirrors preferably situated near each other so that the two
mirrors can be mounteond a common bulkhead, not shown. The secondary and
quaternary mirrors are both negative convex mirrors preferably likewise
situated near each other so that they can be mounted on a second bulkhead,
also not shown. The separation between the two bulkheads is preferably
between one quarter and one third of the effective focal length of the
telescope system. The axes of symmetry of all four mirrors are common such
that the vertices and centers of curvature of all parent surfaces lie on a
common axis. This axis is tilted by several degrees with respect to a
light beam arriving at an entrance plane from the object so as to permit
the beam to pass through the system without encountering any obscuration
by the mirrors.
The primary, tertiary and quaternary mirrors can be described as eccentric
sections of larger parent surfaces. Only mirror sections of larger parent
surfaces are used so as to prevent obscurations that may block light from
the object from passing completely through the telescope optical path. The
primary mirror is preferably an eccentric section of a parent concave
hyperboloid of revolution. The secondary mirror is preferably a mild,
circularly symmetric section of a parent convex ellipsoid mildly deviating
by only microns, that is, a few optical wavelengths from a true spherical
surface for ease of manufacture. The tertiary mirror is preferably an
eccentric section of a parent concave sphere. The quaternary mirror is
preferably an eccentric section of a parent convex sphere. An eccentric
section of a sphere may be fabricated as a symmetric surface by defining a
new fabrication axis which passes through the physical center of the
mirror and the center of curvature of the spherical parent surface.
Secondary and quaternary mirrors are preferably small mirrors as compared
to the primary and tertiary mirrors. The secondary and quaternary mirrors
are both smaller than the effective system aperture for reduced cost and
weight.
The secondary mirror is the limiting aperture, or aperture stop, of the
system. Bundles of light from all points in the field of view are
reflected from the same area on the secondary mirror surface. The diameter
of the secondary mirror limits the size of the bundles of light from all
points in the field, and therefore determines the brightness of the image
and the amount of diffraction present. The secondary mirror is preferably
symmetric about the common mirror axis of the telescope. The secondary
mirror is, therefore, preferably circular in shape and radially symmetric
in surface profile, as opposed to the primary, tertiary, and quaternary
mirrors which may be elongated in one dimension to accommodate the wide
field of view and may be slightly oversized so as not to limit the size of
any of the light bundles traveling through the system. An entrance pupil,
or effective entrance aperture, is the image of the secondary mirror
formed by the primary mirror. In the preferred form, the entrance pupil is
located on the opposite side of the primary mirror away from the object.
The diameter of the entrance pupil is equal to the effective aperture
size. The size of the entrance pupil determines the size of the light
bundle that enters the telescope from each point on the object. An
entrance plane is an arbitrarily defined portal entrance through which
object light passes enroute to the primary mirror. The entrance plane has
no effect on system performance and is usually located on the telescope
periphery.
In exemplary form, the effective focal length of the telescope may be many
times, for example, twelve times, the size of the effective system
aperture for high power, high resolution imaging that is diffraction
limited. High resolution imaging is further enhanced by available detector
technology disposed upon a focal surface. The focal surface is preferably
located near the tertiary mirror and may be flat, but is preferably curved
to provide sharper imagery. More particularly, the focal surface is
preferably a linear section of a parent concave cylinder. The linear focal
surface length depends on the field of view of the system. Preferably, the
focal surface detector array is formed from an assembly of smaller
detector devices, for example, charge coupled devices. The detectors are
positioned to follow the cylindrical contour to maintain sharp focus. The
length of the focal surface and the horizontal dimensions of the primary,
tertiary and quaternary mirrors accommodate the desired linear field of
view. The detector array is aligned to the linear focal surface. The focal
array may extend for a small distance, for example the equivalent of 0.5
degrees in object space, in a direction parallel to the cylinder axis to
accommodate multiple lines of detectors. The additional multiple detector
lines can provide multi-color imaging or provide increased signal to noise
ratio. Additional multiple detector lines used with time delay and
integration signal acquisition may provide increased signal to noise
ratios for improved image quality. As may now be apparent, the preferred
four minor telescope uses at least two spherical surfaces and a
cylindrical focal surface. The tertiary and quaternary mirror are
preferably spherical, while the secondary mirror is preferably a mild
ellipsoid, all easily manufacturable. The reflective system requires only
one mirror of any significant asphericity and fabrication of it is well
known by those skilled in the art.
FIG. 5 shows the modulation transfer function of the specific embodiment
system of FIGS. 3 and 4 having a focal ratio of f/12.3 and a full linear
field of view of 5.6 degrees. The performance is nearly diffraction
limited over the entire field. In the graph, the top line is the
diffraction limit, and the system performance approaches the diffraction
limit within a field of view of .+-.2.8 degrees. In FIG. 5, diffraction is
calculated at a nominal wavelength of 560 nm, representative of
wavelengths in the visible spectrum. The diffraction limit is wavelength
dependent.
Certain parameters are necessary to define a specific embodiment of the
preferred form. The preferred telescope is for collecting the image of a
distant object projecting an object image and for focusing the collected
image onto a focal surface using a arrangement of four reflective mirrors.
The telescope has a common telescope axis relative to the axes of the
mirrors. The primary mirror is a concave reflective mirror having a parent
surface centered about the common axis and is used to collect and reflect
the image of the distant object. The image follows an image path from the
object. The image path is angularly tilted from the common telescope axis.
The secondary mirror is convex reflective mirror also centered about the
common telescope axis. The secondary mirror is for receiving and
reflecting the object image reflected from the primary mirror. The
tertiary mirror is a concave reflective mirror having a parent surface
also centered about the common axis and is for receiving and reflecting
the object image reflected from the secondary mirror. The quaternary
mirror is a convex mirror having a parent surface also centered about the
common telescope axis and is for receiving and reflecting the object image
reflected from the tertiary mirror. The primary mirror is preferably an
eccentric section of a concave hyperboloid of revolution. The tertiary
mirror is preferably an eccentric section of a concave sphere. The
quaternary mirror is preferably an eccentric section of a convex sphere.
The secondary mirror is preferably a mild circularly symmetric convex
ellipsoid.
The telescope further includes a plurality of detectors disposed along the
focal surface. The plurality of detectors may be a linear array of charge
coupled devices aligned as a concave cylindrical linear array providing
detector limited image resolution of the object's image. The telescope is
defined by a field of view, an effective focal length and an effective
aperture size. The full field of view is preferably greater than five
degrees. The focal length is preferably greater than twelve times said
effective aperture size. The aperture size is preferably defined by the
size of said secondary mirror providing diffraction limited image
resolution of the object image.
Structurally, the telescope preferably includes a first bulk head, not
shown, supporting the secondary and quaternary mirrors and defining an
entrance plane, and preferably includes a second bulk head, not shown,
supporting the primary and tertiary mirrors. In the preferred form, the
focal length may be 6218 mm, with a field of view that may be .+-.2.8
degrees. Diffraction limited imagery is achieved. The primary concave
mirror and secondary convex mirror together define an entrance pupil
preferably having a diameter 505 mm which is equal to the effective
aperture size at a preferred nominal wavelength of 560 nm. The angular
tilt of the common telescope mirror axis may be 5.degree. with respect to
the light rays arriving from the object. The primary mirror is preferably
an eccentric section of a concave hyperboloid of revolution having a
preferred radius of curvature of 6538.649 mm, a preferred conic
coefficient of -1.954, and a preferred spacing of 1,600.00 mm from the
entrance plane and preferably in the shape of an oblong. The conic
coefficient describes the shape of the conic aspheric surface. It is
defined as the negative of the square of the eccentricity of the conic
section. The conic coefficient of a sphere is 0. The conic coefficient of
an ellipsoid is between 0 and -1. The conic coefficient of a paraboloid is
-1, and that of a hyperboloid is less than -1. The secondary mirror is
preferably a mild circular convex ellipsoid having a preferred radius of
curvature of 2292.043 mm, a preferred conic coefficient of -0.773, a
preferred spacing of 1,599.15 mm from the primary mirror, and is
preferably circular with a preferred diameter of 258 mm. The tertiary
mirror is preferably an eccentric section of a concave sphere having a
preferred radius of curvature of 3971.116 mm, a preferred conic
coefficient of 0.0, a preferred spacing of 1,688.923 mm from the secondary
mirror, and is preferably oblong. The quaternary mirror is preferably an
eccentric section of convex sphere having a preferred radius of curvature
8513.561 mm, a preferred conic coefficient of 0.0, a preferred spacing of
1,800.00 mm from the tertiary mirror and is preferably oblong. The focal
surface is preferably a section of a concave cylinder having a preferred
radius of curvature of 3342.075 mm, a preferred conic coefficient of 0.0,
and defining a linear focal surface having a spacing of 1999.802 mm from
the quaternary mirror.
While the all reflective four mirror telescope may be improved and modified
by those skilled in the art, for instance by changing spherical surfaces
to aspheric surfaces or conic aspherics to general aspherics to increase
the field of view, those improvements and modifications may nonetheless
fall within the spirit and scope of the following claims.
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